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R. Lacey, SUNY Stony Brook The PHENIX Flow Data: Current Status Justin Frantz (for T.Todoroki) Ohio University WWND 15 Keystone, CO 1 (Filling in For Takahito Todoroki, his suggestions + A. Taranenko’s slides)
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R. Lacey, SUNY Stony Brook PHENIX v n Measurements at RHIC 1)Introduction / Methods 2)NOT : Azimuthal anisotropy in small systems: NOT d+Au and 3 He+Au at 200GeV : Paul Stankus Talk Later This Morning 3)System size dependence of anisotropy? 4)Energy Scan Results 5)PID V n results confronting theory 2 22 33 44
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R. Lacey, SUNY Stony Brook Motivation: “Solving” Hydro To get from here to here we need: 3 Lots O’ Data Shape = ?
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R. Lacey, SUNY Stony Brook PHENIX Methods: Event Plane v n’ s 4 Correlate hadrons in central Arms with EVENT PLANE (RXN, etc) (I) (II) ∆φ correlation function for EP N - EP S ∆φ correlation function for EP - CA Central Arms (CA) |η’| < 0.35 (particle detection) ψ n RXN (| |=1.0~2.8) MPC (| |=3.1~3.7) BBC (| |=3.1~3.9) From 2012: - FVTX (1.5<| |<3)
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R. Lacey, SUNY Stony Brook 5 ψ n RXN (| |=1.0~2.8) MPC (| |=3.1~3.7) BBC (| |=3.1~3.9) Phys. Rev. Lett. 105, 062301 (2010) V n (EP): Phys.Rev.Lett. 107 (2011) 252301 Good agreement between V n results obtained by event plane (EP) and two-particle correlation method (2PC) No evidence for significant η-dependent non-flow contributions from di-jets for pT=0.3-3.5 GeV/c. Systematic uncertainty : event plane: 2-5% for v2 and 5-12% for v3. arXiv:1412.1038, arXiv:1412.1043arXiv:1412.1038arXiv:1412.1043 PHENIX Methods: History/Non-Flow
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R. Lacey, SUNY Stony Brook Using RHIC’s Flexibility 6 harmonic n v2v2 v3v3 200 GeV 62 GeV 39 GeV Species Au+Au Cu+CuCu+Au v1v1 v4v4 Open up new axes
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R. Lacey, SUNY Stony Brook Recent PHENIX publications on flow at RHIC: 1) 2) Recent PHENIX publications on flow at RHIC: 1) Systematic Study of Azimuthal Anisotropy in Cu+Cu and Au+Au Collisions at 62.4 and 200 GeV: arXiv:1412.1043 2) Measurement of the higher-order anisotropic flow coefficients for identified hadrons in Au+Au collisions at 200 GeV : arXiv:1412.1038 7 5
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R. Lacey, SUNY Stony Brook v4v4 PHENIX Data: Preview 8 Species We are filling up this three dimensional space in PHENIX with more and more precision harmonic n v2v2 v3v3 200 GeV 62 GeV 39 GeV Au+Au Cu+CuCu+Au
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R. Lacey, SUNY Stony Brook Different (LARGE) Heavy Collisions Systems 9 Species harmonic n v2v2 v3v3 200 GeV 62 GeV 39 GeV Au+Au Cu+CuCu+Au v1v1 v4v4 First focus on symmetric systems
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R. Lacey, SUNY Stony Brook 10 Flow in symmetric colliding systems : Cu+Cu vs Au+Au 10 Phys.Rev.Lett. 107 (2011) 252301 Strong centrality dependence of v 2 in AuAu, CuCu Weak centrality dependence of v 3 Simultaneous measurements of v2 and v3 Crucial constraint for η/s Updates for HYDRO constraints from Cu+Cu?
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R. Lacey, SUNY Stony Brook v 3 Au+Au vs. Cu+Cu Within largish errors over larger p T the same But some constraining power at low pt (0-1 GeV/c) 11
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R. Lacey, SUNY Stony Brook Should Cu+Au be on this axis? 12 Species harmonic n v2v2 v3v3 200 GeV 62 GeV 39 GeV Au+Au Cu+CuCu+Au v1v1 One of the motivations for Cu+Au was “exotic” configurations? Fair to put it on this axis?
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R. Lacey, SUNY Stony Brook 13 Centrality/Pt dependence of v 2, v 3 in 200 GeV Cu+Au 13 - Centrality dependence of v 2 v 3 similar to Au+Au… - What? No Significant centrality dependence of v 3 ! Same centrality dependence as seen in symmetric collisions: Au+Au and Cu+Cu
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R. Lacey, SUNY Stony Brook 14 v 3 in 200 GeV Cu+Au vs Cu+Cu/Au+Au The observed system size independence of v 3 Is expected from the similar values of ɛ 3 Phys.Rev. C84 (2011) 067901
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R. Lacey, SUNY Stony Brook Should Cu+Au be on this axis? 15 Species harmonic n v2v2 v3v3 200 GeV 62 GeV 39 GeV Au+Au Cu+CuCu+Au v1v1 Answer: Yes : I.S. fluctuations are more important/dominant than overlap shapes! (at least for v 3 )
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R. Lacey, SUNY Stony Brook 16 v2, in 200 GeV Cu+Au vs Cu+Cu/Au+Au 16 Phys.Rev. C84 (2011) 067901 The observed system size dependence of v2: AuAu>Cu+Au>CuCu originate from the differences in initial ɛ 2 Overlap region of course does affect v 2
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R. Lacey, SUNY Stony Brook Note: Caveat v 1 ? 17 Species harmonic n v2v2 v3v3 200 GeV 62 GeV 39 GeV Au+Au Cu+CuCu+Au v1v1 Evidence of exotic overlaps making a difference?: v1 possibly
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R. Lacey, SUNY Stony Brook Note: Understanding v 1 18
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R. Lacey, SUNY Stony Brook Energy Scan 19 Species We have energy scan data for Au+Au both v 2, v 3, v 4 harmonic n v2v2 v3v3 200 GeV 62 GeV 39 GeV Au+Au Cu+CuCu+Au v1v1 For Cu+Cu we have it just for v 2 v4v4
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R. Lacey, SUNY Stony Brook Incl. Hadron v 2 Au+Au, 39-200 GeV 20 No significant change in v 2 (p T ) for √s = 39 -200 GeV ! Precision Data
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R. Lacey, SUNY Stony Brook v2 in CuCu/AuAu collisions at 62.4-200 GeV 21 Eccentricity scaling is broken. Just the transverse size R in the ecc model or could there be implications for viscosity? HYDRO? 5 σ x & σ y RMS widths of density distribution defined in Glauber MC
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R. Lacey, SUNY Stony Brook E.g. Data-based 1/R Scaling Model Interpretation 22 PRL112, 082302(2014) Lacey et.al. 1/R Scaling Model: viscosity is the difference? Interesting to see what REAL HYDRO MODEL will say!
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R. Lacey, SUNY Stony Brook Good Old Au+Au 23 Species harmonic n v2v2 v3v3 200 GeV 62 GeV 39 GeV Au+Au Cu+CuCu+Au v1v1 Step Back Any new information here? ADD PID (another dimension) v4v4
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R. Lacey, SUNY Stony Brook 24 v 2, v 3, v 4 of Identified charged hadrons Au+Au at 200 GeV arXiv:1412.1038
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R. Lacey, SUNY Stony Brook Scaling Properties of Vn Flow at 200 GeV 25 arXiv:1412.1038 NCQ-scaling holds well for v 2,v 3,v 4 below 1GeV in KE T space, at 200GeV v n is related to v 2
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R. Lacey, SUNY Stony Brook Model Constraints from All Moments 26 We all know what a big constraint the vn has been
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R. Lacey, SUNY Stony Brook Break the Glb/KLN ambiguity? Can we resolve this with PID? 27 Private Communication: Shen, C. et. al. arXiv:1110.3033
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R. Lacey, SUNY Stony Brook Model Comparisons v2/v3 ratio MCKLN works better for peripheral Glauber better for most central –We need a new model / New physics effect? 28 Private Communication: Shen, C. et. al. arXiv:1110.3033
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R. Lacey, SUNY Stony Brook Some More Space Filled in with Cu+Cu 29 Species harmonic n v2v2 v3v3 200 GeV 62 GeV 39 GeV Au+Au Cu+Cu Cu+Au v1v1 We also have newly finalized PID’d Cu+Cu v 2 ! Au+Au
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R. Lacey, SUNY Stony Brook 30 v 2 of Identified charged hadrons Au+Au/Cu+Cu at 200 GeV arXiv:1412.1043 Which hydro parameters/inputs would be needed match the Cu+Cu data as well?
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R. Lacey, SUNY Stony Brook Summary PHENIX is filling in the 3-D (5-D!) space! Already confronting Theory adding more constraints to our field’s hoped-for “Solving” of Hydro 31 Anxious to see more of this and other RHIC data included!
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R. Lacey, SUNY Stony Brook 32 Backup Slides
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R. Lacey, SUNY Stony Brook more on v1 thing 33
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R. Lacey, SUNY Stony Brook 34 centrality (%) n=2 RXN n=3 RXN n=4 RXN n=2 MPC n=3 MPC n = 200GeV Au+Au PHENIX Preliminary PHENIX Flow Measurements : Event Plane Resolution ψ n RXN (| |=1.0~2.8) MPC (| |=3.1~3.7) BBC (| |=3.1~3.9) Overall good event plane resolution for V n measurements and study beam energy dependence of the flow.
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R. Lacey, SUNY Stony Brook 35 Differential v 2 (p T ): Comparison with STAR Multi-particle methods Ratio V 2 {STAR} / V 2 {PHENIX EP} < 1.0 for 4p cumulant and LYZ method. LYZ : Lee-Yang-Zeros Method Lee-Yang-Zeros Method 4p cumulant method
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R. Lacey, SUNY Stony Brook Some More Space Filled in with Cu+Cu 36 Species harmonic n v2v2 v3v3 200 GeV 62 GeV 39 GeV Au+Au Cu+CuCu+Au v1v1 Au+Au v4v4
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